1
Antifungal symbiotic peptide NCR044.1 exhibits unique structure and multi-faceted
mechanisms of action that confer plant protection
Siva L. S. Velivelli1, Kirk J. Czymmek1,2, Hui Li1, Jared B. Shaw3, Garry W. Buchko3,4, and
Dilip M. Shah1
1Donald Danforth Plant Science Center, St Louis, MO. 63132, USA
2Advanced Bioimaging Laboratory, Donald Danforth Plant Science Center, St Louis, MO.
63132, USA
3Earth and Biological Sciences Directorate, Pacific Northwest National Laboratory, Richland,
WA 99354, USA
4School of Molecular Biosciences, Washington State University, Pullman, WA 99164, USA
Correspondence and requests for materials should be addressed to D.M.S. (Email:
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Abstract
NCR044.1 is a 36-amino acid nodule-specific cysteine-rich antimicrobial peptide expressed in
the developing nodules of Medicago truncatula. Here, we determined its unique NMR structure
to be largely disordered, one four-residue α-helix and one three-residue anti-parallel β-sheet
stabilized by two disulfide bonds, suggesting it is highly dynamic. NCR044.1 exhibited potent
fungicidal activity against multiple plant fungal pathogens. It breached the fungal plasma
membrane, bound to multiple phosphoinositides, and induced reactive oxygen species. Time-
lapse confocal and super-resolution microscopy revealed strong fungal cell wall binding,
penetration of the cell membrane at discrete foci, followed by gradual loss of turgor, and
subsequent accumulation in the cytoplasm with elevated levels in nucleoli. Nucleolar localization
of NCR044.1 was unique amongst plant antifungal peptides, suggesting its potential interaction
with ribosomes and inhibition of translation. Spray-applied NCR044.1 significantly reduced gray
mold disease symptoms caused by the fungal pathogen Botrytis cinerea in tomato plants and
post-harvest products demonstrating its potential as a spray-on peptide-based biofungicide.
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Medicago truncatula, a model legume of the inverted repeat-lacking clade (IRLC), forms an
agriculturally important nitrogen-fixing endosymbiotic relationship with the Gram-negative
bacterium Sinorhizobium meliloti1. This relationship results in the formation of indeterminate
nodules on the plant’s roots whose continued peaceful existence depends on the mutual exchange
of signals between the host and its natural symbiotic bacterial partner. After endocytosis into the
cytoplasm of specialized nitrogen-fixing nodule cells, microsymbiont S. meliloti undergoes a
remarkable irreversible differentiation process leading to the formation of enlarged polyploid
bacteroides. This terminal differentiation process is orchestrated by 639 nodule-specific cysteine-
rich (NCR) peptides expressed in successive spatio-temporal waves during nodule development2-
4. Genetic studies have revealed that the absence of specific NCR peptides results in the
breakdown of the symbiotic relationship and the cessation of nitrogen-fixation in M. truncatula5-
7.
NCR peptides are directed to the plant-derived symbiosome containing bacteroids via the
plant secretory pathway. Thus, each peptide is synthesized as a larger precursor peptide
containing the amino-terminal endoplasmic reticulum targeting signal and the mature peptide.
Mature NCR peptides are 30-50 amino acids in length but highly variable in their primary amino
acid sequences and net charge. They are characterized by the presence of either four or six
conserved cysteines presumably involved in formation of two- or three intramolecular disulfide
bonds. NCR peptides are defensin-like since their predicted disulfide bonding patterns exhibit
similarity with those of mammalian defensins. A subset of 639 NCR peptides is cationic with a
net charge ranging from +3 to +11 and is also rich in hydrophobic residues8. Defensin-like NCR
peptides exhibit potent antibacterial activity in vitro against symbiotic rhizobial bacteria and
against various Gram-negative and Gram-positive bacteria9-11. For example, NCR247 has
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antibacterial activity against free-living S. meliloti at high concentrations but induces bacteroid-
like features at low concentrations. A mode-of-action (MOA) study showed that NCR247 blocks
cell division, induces cell elongation, and formed complexes with bacterial ribosomal proteins
affecting protein synthesis and the bacterial proteome12. Since M. truncatula expresses several
cationic NCR peptides, it is likely that they exhibit different modes of antibacterial action in
different compartments of the nodule13.
In a recent study, 19 cationic NCR peptides were tested for their ability to inhibit the growth
of a clinically relevant human fungal pathogen Candida albicans. Of these, nine with a net
charge above +9 killed this fungal pathogen efficiently, showing inhibitory effects on both the
yeast and hyphal forms at concentrations ranging from 1.5 to 10.5 µM14, demonstrating their
potential for development as antifungal drugs14. The subcellular localization and intracellular
targets of these peptides in fungal cells remain to be determined. There are several cationic NCR
peptides with sequence heterogeneity expressed in the nodules of M. truncatula and other IRLC
legumes and it is likely that at least some of them will have potent antifungal activity against
plant fungal pathogens and will be unique in structure and MOA.
In this study, we showed that NCR044.1, a 36-amino acid peptide with a net charge of +914,
exhibited potent antifungal activity against plant fungal pathogens. However, its 3D structure
was determined to be very different from other well characterized plant antifungal peptides such
as defensins, thionins, lipid-transfer proteins, thaumatins, and heveins15. This is the first 3D
structure of any NCR peptide and also the first antifungal plant peptide reported to target the
nucleolus in fungal cells where it presumably binds to ribosomes and inhibits translation.
NCR044.1 conferred strong resistance to B. cinerea when applied topically on lettuce leaves and
rose petals. Young tomato and Nicotiana benthamiana plants sprayed with this peptide were also
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protected from the gray mold disease caused by this pathogen indicating the potential of
NCR044.1 as a peptide-based fungicide. Our work illustrates the novel antimicrobial activity of
NCR peptides and paves the way for development of these peptides as spray-on peptide-based
biofungicides.
Results
Two NCR044 homologs are expressed in the nodules of M. truncatula
The M. truncatula genome contains genes encoding two NCR044 homologs, NCR044.1
(MtrunA17_Chr7g0216231) and NCR044.2 (MtrunA17_Chr7g0216241). The gene for each
peptide encodes a signal sequence and a mature peptide. The mature peptides are each 36-amino
acids in length and share 83% sequence identity (Fig. 1a). NCR044.1 has a net charge of +9 and
38% hydrophobic residues, whereas NCR044.2 has a net charge of +8 and 36% hydrophobic
residues (Fig. 1b). Only two amino acid substitutions (I17P and R36S) account for the difference
in net charge and hydrophobicity. The sequence of each mature peptide has a remarkably high
concentration of cationic residues in the carboxy-terminal half of each molecule. The primary
sequence of each peptide displays no significant homology with any of the peptide sequences in
the Antimicrobial Peptide Database (http://aps.unmc.edu/AP/main.php)16.
During development of indeterminate nodules, NCR044.1 and NCR044.2 transcripts are each
highly expressed in the interzone II-III and the nitrogen-fixation zone ZIII and relatively lowly in
the distal and proximal parts of the infection or differentiation zone (FIId and FIIp) (Fig. 1c, d)17.
The biological function of each peptide during nodule development and nitrogen fixation
remains to be determined.
Expression of recombinant NCR044.1 in Pichia pastoris and mass spectral analysis of the
purified peptide
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In order to generate the NCR044.1 peptide with correctly formed disulfide bonds, the NCR044.1
gene was expressed in a heterologous Pichia pastoris expression system. The peptide secreted
into the growth medium was successfully purified using cation exchange and C18 reverse phase
HPLC. Mass spectral analysis revealed a molecular mass of 4311.28 Da for the purified product
(Supplementary Fig. 1a, b) as expected for disulfide-linked NCR044.1.
Disulfide bonding pattern in NCR044.1
NCR044.1 contains four cysteine residues (C9, C15, C25, C31) with three possible patterns of
intramolecular disulfide bond formation and multiple patterns of intermolecular disulfide
formation. Since the intra- and intermolecular pattern of disulfide bond formation will
significantly affect the peptide’s structure, and likely its function, it is important that oxidation is
primarily intramolecular and the pattern of oxidation in NCR044.1 is homogeneous. NMR
measurement of the peptide’s rotational correlation time (τc), 3.6 ± 0.5 ns, was consistent for a
~4.0 kDa peptide18 indicating it was primarily monomeric in solution with no detectable
intermolecular disulfide bond formation.
Fig. 2a and 2b show the assigned 1H-15N HSQC spectra for the oxidized and reduced
forms of NCR044.1. For oxidized NCR044.1 (Fig. 2a), the wide chemical shift dispersion of the
amide resonances in both the proton and nitrogen dimensions are characteristic features of a
structured protein19. A single set of cross peaks that could all be assigned suggests one dominant
species is present with a homogeneous intramolecular disulfide bond pattern. Disulfide bond
formation in NCR044.1 was unambiguously verified from the NMR chemical shifts of the β-
carbon of cysteine residues. Generally, the cysteine 13Cβ chemical shift in the oxidized state is
>35 ppm and decreases to <32 ppm in the reduced state20. In the absence of tris(2-
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carboxyethyl)phosphine (TCEP) or other reducing agents the cysteine 13Cβ chemical shifts for
NCR044.1 were 38.0 ppm or greater, as indicated in Supplementary Table 1, clearly indicating
that cysteine residues were oxidized and incorporated in disulfide bonds. These 13Cβ chemical
shifts decreased to 28 ppm or less in the presence of 5 mM TCEP, a significant change indicating
that disulfide bonds were ablated.
While the chemical shift data indicated disulfide bonds were present, it was not possible
to use preliminary structure calculations to deduce unambiguously the disulfide bond pairs from
1H-1H NOEs due to the consequences of proximal γ-sulphur atoms. Instead, the disulfide bond
pattern was deduced from the analysis of mass spectral data for trypsin-digested, unlabeled
peptide in the reduced and oxidized states. This data showed that disulfide linkages were C9-C30
and C15-C25. Note that the disulfide bonds are essential for the stability of the peptide’s tertiary
structure21 as illustrated in the 1H-15N HSQC spectrum for reduced NCR044.1 in Fig. 2b. The
range of chemical shift dispersion of amide resonances was greatly compressed relative to the
oxidized NCR044.1 (Fig. 2b), a characteristic feature of disordered proteins19.
Solution NMR structure of NCR044.1
Fig. 2c is a superposition of the final ensemble of structures calculated for NCR044.1 (PDB:
6U6G) with a single cartoon representation of this ensemble shown in Fig. 2d. The most striking
feature is the paucity of canonical elements of secondary structure in the peptide. NCR044.1
contains one short (A23-R25, G28-C30) anti-parallel β-sheet and a “whif” (S11-E14) of an α-
helix. The rest of the peptide was largely disordered and dynamic, even with the tethering
afforded by the two disulfide bonds. A search for structures in the PDB similar to NCR044.1
with the DALI server22 generated no hits, suggesting this structure was new to the PDB. The
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disorder in the structure was reflected in the paucity of 1H-1H NOEs observed in the NOESY
NMR data. As shown in Supplementary Table 2, most of the NOEs were intra-residue with only
12 long range NOEs observed. The prevalent disorder was also reflected in the analysis of the
13Cα and 13Cβ chemical shifts. Deviations of 13Cα and 13Cβ chemical shifts from random coil
values are predictive of canonical α-helical (positive Δδ13Cα, negative Δδ13Cβ) and β-strand
(negative Δδ13α, positive Δδ13Cβ) secondary structure21,23. These deviations from random coil
values were plotted for oxidized and reduced NCR044.1 in Fig. 2e and showed modest
correlation for their respective short elements of the secondary structure identified in the NMR
structure calculations for the oxidized peptide. Upon reducing the disulfide bonds in the presence
of 5 mM TCEP, aside from the N-terminal region (A1 – I10) which was largely disordered in the
oxidized state to begin with, these modest correlations disappear with most of the chemical shift
values not significantly differing from random coils values. These observations suggest the
disulfide bonds play a significant role in stabilizing the structure of the oxidized peptide and in
their absence the peptide was largely disordered with little transient structure.
NCR044.1 exhibits potent antifungal activity against plant fungal pathogens
Chemically synthesized NCR044.1 was previously reported to exhibit fungicidal activity against
the human fungal pathogen C. albicans at low micromolar concentrations8. Here, we determined
the antifungal activity for recombinant NCR044.1 against a panel of closely related plant fungal
pathogens, Fusarium spp. and B. cinerea, using a spectrophotometric assay. NCR044.1 inhibited
the growth of B. cinerea at low micromolar concentration with an IC50 value of 1.55 ± 0.21 µM
(Fig. 3a). NCR044.1 also inhibited the growth of F. graminearum and F. virguliforme with IC50
values of 1.93 ± 0.23 and 1.68 ± 0.20 µM, respectively. F. oxysporum was the most sensitive to
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NCR044.1 with an IC50 value of 0.52 ± 0.01 µM (Fig. 3a). The resazurin cell viability assay
revealed that F. oxysporum cells were killed at a concentration of 1.5 µM, whereas other fungi,
including B. cinerea, were killed at a concentration of 3 µM (Fig. 3b and 3c).
NCR044.1 disrupts the plasma membrane of B. cinerea
Antifungal peptides are known to interact with phospholipid bilayers and disrupt the plasma
membrane15. We postulated that the antifungal activity of NCR044.1 occurred via membrane
permeabilization. Using a SYTOXTM Green (SG) assay, a non-fluorescent intercalating dye that
permeates fungal cells when their plasma membrane integrity is compromised, we tested the
ability of NCR044.1 to cross the plasma membrane of B. cinerea.
The uptake of SG in B. cinerea conidia and germlings treated with 3 µM NCR044.1 for
15 min was first monitored using confocal microscopy. The nuclei of both conidia and germlings
were stained with SG, suggesting compromised cellular membrane integrity induced by
NCR044.1 (Fig. 4a-d). The kinetics of membrane permeabilization was determined in B. cinerea
germlings treated with various concentrations of NCR044.1 every 30 min for up to 3 h. In
NCR044.1 treated fungal cells, permeabilization of the plasma membrane was observed within
30 min and reached its maximal level at 120 min. The rate of membrane permeabilization
increased with increasing concentrations of NCR044.1 as shown in Fig. 4i. To test if membrane
disruption was sufficient for antifungal activity of NCR044.1 in ungerminated B. cinerea spores,
we incubated spores in 3 µM NCR044.1 for 1 h, washed off free peptide, and then allowed the
spores to germinate for 24 h at room temperature in peptide-free growth medium. Our data
showed that B. cinerea spores were able to resume their growth (Fig.4j-l) in peptide-free growth
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medium suggesting membrane permeabilization alone is insufficient to induce death of fungal
cells by the peptide.
NCR044.1 elicits rapid production of ROS in B. cinerea germlings, but not in conidia
Antimicrobial peptides with different mode of action are known to induce ROS and cause cell
death through apoptosis or necrosis-like processes24,25. To determine if NCR044.1 elicited
production of ROS, we challenged the conidia and germlings of B. cinerea with 3 µM of
NCR044.1 for 2 h in the presence of the dye 2′,7′-dichlorodihydrofluorescein diacetate (H2DCF-
DA). Upon intracellular oxidation by ROS, H2DCF-DA is converted into a highly fluorescent
2’,7’-dichlorofluorescein (DCF) that can be monitored using confocal microscopy. ROS
production was observed in germlings, but not in conidia (Supplementary Fig. 2a-d). Real time-
quantification of ROS production was measured spectrophotometrically every 30 min for up to 2
h with untreated germlings and germlings treated with 3 µM NCR044.1. Rapid induction of ROS
fluorescence within 30 min was observed and the fluorescence intensity increased in a time- and
dose-dependent manner. The highest fluorescence intensity was observed at 3 µM suggesting the
elicitation of oxidative stress by ROS in germlings following NCR044.1 treatment
(Supplementary Fig. 2i).
NCR044.1 binds to multiple membrane phospholipids
Several plant defensins have been shown to recruit plasma membrane-resident phospholipids as
part of their MOA26,27. Using the protein-lipid overlay assay, we assessed the ability of
NCR044.1 to bind different bioactive membrane phospholipids. NCR044.1 strongly bound to
phosphatidylinositol 3,5-bisphosphate (PI(3,5)P2). It also bound weakly to multiple other
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phosphoinositides and to phosphatidic acid (PA) (Fig. 5a, b). To further investigate the
phospholipid-binding specificity of NCR044.1, a polyPIPosome assay was performed with
polymerized-liposomes. As shown in Fig. 5c, NCR044.1 bound strongly to liposomes that
contained PC:PE:PI(4)P and PC:PE:PI(3,5)P2 and weakly to PC:PE containing liposomes.
NCR044.1 interacts with PI3P to form a large molecular weight complex
On the basis of the above protein-phospholipid overlay assay, we conducted an NMR chemical
shift perturbation study with 15N-labeled oxidized NCR044.1 and PI(3)P to further corroborate
phospholipid binding, and ideally, identify the lipid binding surface of NCR044.1. This
experiment is based on the premise that backbone amide protons are sensitive to their molecular
environment, and consequently, it is possible to identify the surface of ligand binding to a
polypeptide by following amide chemical shift (or intensity) perturbations in 1H-15N HSQC
spectra following the titration of ligand into the sample28,29. For NCR044.1, no chemical shift
perturbations were observed over the titration range, but the intensity of the amide cross peaks
was observed to decrease starting at a PI(3)P:NCR044.1 molar ratio of 9.4:1. As shown in
Supplementary Fig. 3a, there were remnants of only 12 amide cross peaks at a PI(3)P:NCR044.1
molar ratio of 18.8:1. These intensity perturbations in the 1H-15N HSQC spectra of NCR044.1
showed that the peptide was interacting with PI(3)P30. This was corroborated by overall
rotational correlation time (τc) measurements of the peptide at each titration point that increased
from 3.6 ± 0.5 ns in the absence of PI(3)P to 8.7 ± 2.5 ns at a PI(3)P:NCR044.1 molar ratio of
18.8:1. The latter τc value corresponded to a molecular weight in the 15 kDa range18. Because
amide cross peaks should be readily detectable in the 1H-15N HSQC spectrum of an ~15 kDa
species, potential explanations for the disappearing amide resonances include (i) heterogeneous
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binding to the phospholipid that generates multiple different chemical environments for the
peptide with populations that cannot be detected and (ii) dynamic interactions with a large
molecular complex formed by PI(3)P in solution. To the best of our knowledge, the solution
properties of PI(3)P have not been characterized at high concentrations. However, given the
aliphatic tails on one end of the molecule and the hydrophilic inositol head-group on the other
end, it is possible that PI(3)P forms high molecular weight micellar structures at high lipid
concentrations. Interactions between PI(3)P and NCR044.1 are likely electrostatic in nature. The
hydrophilic head-group of PI(3)P contains two negatively charged phosphate groups. As shown
in Supplementary Fig. 3b, the surface of NCR044.1 is dominated by a positively charged surface
that covers the majority of the peptide, providing multiple sites for binding to the hydrophilic
head-group of PI(3)P.
Exogenous NCR044.1 is translocated into the cells of B. cinerea
We used DyLight550-labeled NCR044.1 to examine its intracellular translocation into the B.
cinerea conidia and germling cells. In conidia incubated with 3 µM DyLight550-NCR044.1 for
16 h, the peptide first accumulated on the cell surface, and was subsequently internalized and
diffused throughout the cytoplasm (Fig. 6a, b). We quantified the percentage of conidia cells that
internalized 1.5 and 3 µM DyLight550-labeled NCR044.1 after overnight incubation and
observed a statistically significant difference (p = 0.0057, t = -5.4, df = 4, unpaired Student’s t
test) (Fig. 6c). In conidial cells treated with 1.5 µM peptide, only 18.8% of the cells internalized
peptide into the cytosol. In contrast, this value rose to 47.5% with 3 µM peptide. The membrane
selective dye FM4-64 was subsequently used to determine if DyLight550-labeled NCR044.1 co-
localized with cellular membranes in B. cinerea germlings. In spore heads and germlings,
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NCR044.1 first bound to the cell wall (Fig. 6d-f, arrows) and cell membrane (Fig. 6d-f,
arrowheads). NCR044.1 co-localized with FM4-64 at bright foci at the germ tube tip and small
foci intermittently along the cell periphery of B. cinerea (Fig. 6 g-i, asterisks). This suggested
that this peptide likely interacted with plasma membrane resident phospholipids which
invaginated and/or endocytosed to enter fungal cells. Additionally, we observed that NCR044.1
was distributed diffusely in the cytoplasm and concentrated within the nucleus (Fig. 6d-i, N),
whereas FM4-64 showed clear cytoplasmic membrane profiles and was excluded from the
nucleus, suggesting that NCR044.1 localized at other non-membrane intracellular targets.
Next, we applied time-lapse confocal microscopy to monitor the uptake of 3 µM
DyLight550-labeled NCR044.1 in germlings. The peptide initially was observed associated with
the germling cell wall (Fig. 6j, T=0) and then migrated towards foci at the germ tube tip (Fig. 6d,
T=0, asterisks) or the germ tube and/or conidial walls (Fig. 6j, T=0 through T=9:51, asterisks).
These foci appeared to be the sites of cytoplasmic entry and coincided with a gradual loss of
turgor (Compare Fig 6J T=0 with T=40). Within 15 min, the peptide, in general, was diffusely
localized in the cytoplasm of the germlings and tended to associate with bright spherical
structures consistent with nuclei. Often, entry into the cell was observed as a gradient across the
cell dependent on the origin of plasma membrane breach (Fig. 6j).
Super-resolution microscopy reveals nucleolus as a cellular target of NCR044.1 in B.
cinerea
We applied lattice structured illumination microscopy to clearly identify the subcellular
localization of DyLight550-labeled NCR044.1 in B. cinerea at high-resolution. Since we
determined that DyLight550-labeled NCR044.1 was preferentially localized to the nucleus of B.
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cinerea (Fig. 7a, b), we applied the DNA staining dye DAPI to see if the peptide bound to the
nuclear DNA. As shown in Fig. 7c, DyLight550-NCR044.1 did not co-localize with DAPI in the
nuclei of the germlings cells, and indeed, appeared to be explicitly excluded from nuclear DNA.
We then used the nucleolus-specific RNA staining dye, Nucleolus Bright Green (NBG), to
monitor the co-localization with the peptide. We observed that DyLight550-NCR044.1 strongly
co-localized with NBG (Fig. 7d) suggesting potential interaction with ribosomes. Thus, in B.
cinerea, NCR044.1 appears to be a nucleolus-targeting peptide with potential to form a complex
with ribosomes and impair their function.
Fluorescence Recovery After Photobleaching (FRAP) experiments reveal that NCR044.1
has strong binding affinity to B. cinerea conidia cell walls and increased affinity to the
nucleolus in the cell
In order to understand the mobility of DyLight550-NCR044.1 to specific subcellular domains in
B. cinerea, we performed a series of FRAP experiments (Fig. 8a-e) quantifying the half time of
recovery (τ½) of the mobile fraction and percent immobile fraction. We targeted four distinct
regions; the conidial spore wall, germ tube cell wall, cytoplasm, and nucleoli, using identical
FRAP bleach/recovery acquisition and analysis conditions. Statistically significant differences
(K-Wstatistic = 59.79, df = 3, p < 0.0001) were observed between specific cellular structures and
among the immobile fractions of spore walls versus germ tube walls, cytoplasm, and nucleoli
(pairwise Wilcoxson test, corrected p < 0.0001) (Fig. 8b). Our data showed that the fungal cell
walls had the highest affinity to DyLight550-NCR044.1 with an immobile fraction of 76.7 ±
1.3% (spores) and 24.9 ± 3.3% (germ tubes), while the nucleoli and cytoplasm had greatly
reduced immobile fractions of 15.4 ± 1.9 and 11.7 ± 1.5%, respectively (Fig. 8c). Additionally,
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the τ½ of the mobile fractions revealed a statistically significant difference (K-Wstatistic = 27.81, df
= 3, p < 0.0001) between nucleoli versus cytoplasm (pairwise Wilcoxson test, corrected p < 0.01)
and nucleoli versus cell wall (corrected p < 0.01) (Fig. 8d). Spore walls and nucleoli had the
slowest mobility with a τ1/2 = 36.0 ± 2.4 and 31.4 ± 2.4 seconds, respectively, while the
cytoplasm and germ tube cell walls had the fastest mobility with a τ1/2 = 22.0 ± 1.7 and 20.5 ±
3.4 seconds, respectively (Fig. 8e). Taken together, this data suggested that strong binding of the
spore cell wall by NCR044.1 might serve to anchor it in close proximity to the plasma membrane
and then upon germination, the mobility of NCR044.1 increased, allowing it to breach the cell
membrane and migrate to cytoplasmic targets with preferential affinity to the nucleoli.
NCR044.1 confers resistance to B. cinerea in lettuce leaves and rose petals
NCR044.1 was tested for its ability to reduce symptoms of gray mold disease in planta.
Detached lettuce leaves were drop-inoculated with the conidia of B. cinerea in the presence of
different concentrations of the peptide. Significant differences in disease severity were found
between plants treated with peptide and control plants without peptide treatment (Kruskal-
Wallisstatistic = 31.15, df = 3, p < 0.0001). In particular, lettuce leaves inoculated with the
pathogen in the presence of 6 and 12 µM NCR044.1 displayed significantly smaller lesions 48 h
post-inoculation compared to control leaves sprayed with pathogen only (pairwise Wilcoxson
test, corrected p < 0.0001) (Supplementary Fig. 5a).
NCR044.1 was also tested for its ability to confer resistance to B. cinerea in a rose petal
infection assay. NCR044.1 significantly reduced virulence of the pathogen on rose petals as
compared with control petals without peptide treatment (K-Wstatistic = 76.36, df = 3, p < 0.0001).
Almost complete suppression of disease symptoms was observed at a concentration of 1.5 µM
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peptide compared to rose petals sprayed with pathogen only (pairwise Wilcoxson test, corrected
p < 0.0001) (Supplementary Fig. 5b).
Spray-applied NCR044.1 confers gray mold resistance in N. benthamiana and tomato
plants and is not internalized by plant cells
We tested the potential of NCR044.1 for use as a peptide fungicide for controlling gray mold
disease in young N. benthamiana and tomato plants. At a concentration of 24 µM, NCR044.1
was sprayed onto the leaves of 4-week-old N. benthamiana and 15-day-old tomato plants and
allowed to dry. The Kruskal-Wallis test showed significant differences in disease severity
between different treatment groups of N. benthamiana (K-Wstatistic = 22.75, df = 2, p < 0.0001)
and tomato plants (K-Wstatistic = 29.06, df = 2, p < 0.0001). N. benthamiana and tomato plants
sprayed with the peptide had significantly reduced disease symptoms at 48 h (pairwise
Wilcoxson test, corrected p < 0.01, Fig. 9a, b) and 60 h (pairwise Wilcoxson test, corrected p <
0.01, Fig. 9c, d) post-inoculation, respectively, compared to control plants sprayed with pathogen
only. The photosynthetic efficiency (Fv/Fm) of the control plants (no peptide) exposed to
pathogen was significantly lower compared to plants sprayed with NCR044.1 prior to pathogen
exposure. In an effort to determine if defensin internalization/localization observed in fungi also
occurred with plant cells, we applied a droplet of 24 µM DyLight550-NCR044.1 to the leaf
surface of N. benthamiana and imaged it by confocal microscopy. Our results indicated that
DyLight550-NCR044.1 remained on the plant surface, concentrating at anti-clinal walls, with no
evidence of internalization within the leaf epidermal cells (Supplemental Fig. 6a-i). This data
indicated significant potential for the use of NCR044.1 as a spray-on peptide fungicide for the
control of gray mold disease in vegetables, flowers and other economically important crops.
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17
Discussion
M. truncatula expresses ~639 NCR peptides during the establishment of successful symbiosis
with Sinorhizobium meliloti4. These peptides are thought to be involved primarily in causing
differentiation of the rhizobacteria into bacteroides. However, a subset of these peptides with
high cationicity exhibit antimicrobial activity in vitro and in planta31. Several NCR peptides have
now been shown to exhibit bactericidal activity against various Gram-negative and Gram-
positive bacteria in vitro3,32. Among the hundreds of NCR peptides expressed are two NCR044
peptides that share 83% sequence identity and high cationicity. In this study, we report the
structure, antifungal activity, and MOA of one of these peptides, NCR044.1. In addition, we
demonstrate its potential for control of pre- and postharvest fungal diseases.
Pre- and postharvest fungal diseases cause substantial losses in the yields of many important
crops. These diseases are currently mitigated primarily through application of chemical
fungicides multiple times. Unfortunately, such chemical fungicides pose considerable health and
environmental risks and become ineffective over time due to the evolution of resistance.
Alternative means for control of fungal infections are peptide-based biofungicides applied
topically to plants33. NCR044.1 exhibits potent broad-spectrum antifungal activity in vitro
against four economically important fungal pathogens tested in this study. When applied on the
surface of lettuce leaves and rose petals, it significantly reduces gray mold disease lesions caused
by B. cinerea infection. Moreover, spray application of this peptide controls gray mold disease
symptoms in young tomato and N. benthamiana plants. These results clearly demonstrate the
potential value of NCR044.1 as a spray-on peptide-based biofungicide in agriculture. In contrast
to chemical fungicides, peptide-based “green chemistry” fungicides are sustainable, inexpensive,
and ideal for protection of the environment and consumer health33.
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18
In the inverted repeat-lacking clade legumes such as M. truncatula, defensins and defensin-
like NCR peptides have co-evolved. Defensins are one of the first lines of defense against
harmful pathogens, whereas defensin-like NCR peptides are effectors inducing differentiation of
rhizobia into nitrogen-fixing bacteroids5. Antifungal plant defensins with four disulfide bonds are
diverse in their amino acid sequences but their three-dimensional structures with a highly
conserved cysteine-stabilized α/β motif are strikingly similar34,35. To our knowledge, no three-
dimensional structure of an NCR peptide has been determined to date. The structure of
NCR044.1 reported here appears to be novel, dominated by largely disordered regions. It
remains to be determined if this disordered structure adopts an ordered secondary structure in
membrane-mimetic solutions and contributes to the biochemical function and/or stability of this
peptide. Several hundred NCR peptides expressed in the nodules of M. truncatula also exhibit
significant variation in their amino acid sequences, and therefore, they too may differ
substantially in their structures and antifungal modes of action36.
A common characteristic of antifungal peptides is their ability to permeabilize the plasma
membrane of fungal pathogens. In plant defensins, membrane permeabilization is also an
important early step in their modes of action34,37. Recently, the peptides NCR192, NCR247, and
NCR335 have been reported to disrupt the plasma membrane of C. albicans8. In the mechanistic
studies employing NCR044.1 here, we determined that NCR044.1 quickly binds to the cell walls
of B. cinerea conidia and germlings and subsequently breaches the plasma membrane of these
cells near the attachment sites. Within 30 min after peptide exposure, SYTOX Green uptake was
observed at a dose-dependent rate. Thus, membrane permeabilization is also an early stage in
fungal cell death induced by NCR044.1. This was further supported by our observation that as
cytoplasmic loading of DyLight550-labeled NCR044.1 peptide occurred, it coincided with
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19
concomitant loss of turgor. However, conidial cells exposed to NCR044.1 for a period of 1 h
could subsequently germinate, suggesting membrane permeabilization alone was insufficient to
induce cell death or inhibit conidial germination.
Since several plant defensins bind to plasma membrane resident bioactive phosphoinositides
or related phospholipids to oligomerize and induce membrane permeabilization35, we tested
whether NCR044.1 also bound to specific phospholipids. Like the plant defensins NaD138 and
MtDef539, NCR044.1 bound to several phospholipids in the phospholipid-protein overlay assay.
Of note, it bound more effectively to PI mono/diphosphates, in particular, PI(3,5)P2. Further
studies are needed to decipher the mechanism by which membrane permeabilization is induced
by NCR044.1 and to understand the role phospholipid binding plays in peptide-induced
membrane permeabilization of fungal pathogens.
Inhibition of mitochondrial respiration leads to the generation of ROS that play an important
role in fungal cell death34,35. Using the dye H2DCF-DA, ROS generation was detected in
NCR044.1 challenged germlings, but not the conidia, of B. cinerea. This observation is
consistent with the overall reduced peptide uptake in quiescent spores relative to germ tubes and
the requirement for overnight incubation (Fig. 5a). However, further studies are needed to
unambiguously establish NCR044.1-induced ROS generation as a cause of cell death. In
particular, it will be important to obtain evidence for the induction of the markers of ROS-
mediated oxidative damage, such as protein carbonylation and DNA laddering, that lead to
apoptotic cell death.
Internalization of NCR044.1 into the conidial and germling cells of B. cinerea has been
studied in relation to its antifungal activity. While NCR044.1 internalization by conidia was
slow, it was internalized rapidly by germlings of this pathogen. Our co-localization experiments
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20
with FM4-64, an amphiphilic styryl dye that serves as a marker for endocytosis and vesicle
trafficking, provided important clues about NCR044.1 initial entry into fungal cells. The earliest
signs of internalization of DyLight550-labeled NCR044.1 were often indicated by a single patch
near the germling tip (Fig. 6g, Fig. 6j T=0) and smaller foci just beneath the cell wall (Fig. 6g-i)
which co-labeled with FM6-64. This pattern was similar to that reported for M. truncatula
defensin MtDef5 in Neurospora crassa39 and consistent with the apical vesicle accumulation and
sites of endocytosis observed with FM4-64 and AM4-64 studies in a number of diverse fungi,
including B. cinerea40,41. Once internalized, the peptide appeared to diffuse through the
cytoplasm and NCR044.1 gradients formed (Fig. 6j) that coincided with origins of initial cell
surface foci but no longer matched the classical membrane/vesicle labeled pattern of FM4-64
(Fig. 6d-i). Once cytoplasmic, the peptide localized to nucleoli where it likely bound ribosomal
RNA and/or ribosomal proteins and inhibited protein translation. Interestingly, NCR247 has also
been shown previously to interact with ribosomal proteins in the symbiont S. meliloti12. While
the exact mechanism for nucleolar binding is unknown, electrostatic maps of ribosomal subunits
show large areas of negative potential42 and this property significantly influences interactions
with positively charged proteins43, and conceivably, NCR044.1 with a net charge of +9. It will be
important to determine if other antifungal NCR peptides from IRLC legumes also target nucleoli
in fungal cells. Interaction with ribosomes and inhibition of translation is likely to be a shared
mechanism used by some antifungal NCR peptides12. However, the possibility remains that these
peptides have multiple intracellular targets to induce fungal cell death.
Based on the results reported here, we propose a multistep model for the antifungal action of
NCR044.1 against B. cinerea (Fig. 10). The first step involves binding of the peptide to the cell
wall followed by binding and internalization at putative sites of endocytosis and then disruption
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21
of the plasma membrane via interaction with membrane-resident phospholipids (after spore
germination). The peptide eventually gains entry into the cytoplasm, inducing the formation of
ROS and binding to nucleoli where it likely forms complexes with ribosomal RNA and/or
ribosomal proteins to affect translation. Our data show that NCR044.1 interacts with several
major and diverse cellular components, perhaps permitted by its highly dynamic structure as
determined by NMR, thus allowing broad effectiveness against fungal pathogens. These new
insights necessitate further studies to better understand the relative contribution of each step to
the antifungal action of NCR044.1. Hundreds of NCR peptides expressed in nodules of certain
legumes offer highly diverse antifungal peptide sequence space and this work on NCR044.1
peptide structure and its MOA will help in the design of more effective antifungal peptides for
future use in agriculture.
Methods
Fungal cultures and spore suspensions
The fungal strains Fusarium graminearum PH-1, F. virguliforme NRL 22292 (Mont-1), F.
oxysporum f. sp. Cubense, and Botrytis cinerea T-4 were each cultured in their respective normal
growth medium shown in Supplementary Table 2. Fungal spores were harvested by washing the
fungal growth plates with sterile water. The spore suspension was filtered through two layers of
Miracloth, centrifuged at 13,000 rpm for 1 min, washed, and resuspended in low-salt Synthetic
Fungal Medium (SFM)44. The spore suspension of each fungal pathogen was adjusted to the
target concentration using a hemocytometer.
Recombinant expression and purification of NCR044.1
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The codon-optimized gene encoding NCR044.1 was synthesized by GenScript (Piscataway,
NJ). The NCR044.1 gene was expressed in P. pastoris X33 using either a SacI or PmeI-
linearized pPICZα-A integration vector (Invitrogen, Carlsbad, CA) at XhoI and XbaI restriction
sites in-frame with the α-mating factor secretion signal sequence containing KEX2 without the
Glu-Ala repeats. The peptide product was purified from the culture medium as described
previously45. The lyophilized peptide was dissolved in nuclease-free water and its concentration
determined on a Nanodrop 2000c (Thermo Scientific, Waltham, MA) using A280 with the molar
extinction coefficient (3230 M-1cm-1) and molecular weight (4.3 kDa) of NCR044.1. The purity
and mass of NCR044.1 were verified by sodium dodecyl sulfate-polyacrylamide gel
electrophoresis (SDS-PAGE) and direct infusion-mass spectrometry, respectively.
15N and 13C isotopic labeling of NCR044.1 for NMR structural analysis
The 13C- and 15N-labeled peptide was prepared according to the protocol as described
previously46 with minor modifications. The labeled NCR044.1 was purified from the P. pastoris
growth medium following a protocol similar to the one used for the unlabeled peptide45.
NMR spectroscopy of NCR044.1
All NMR data were collected at 20˚C on a double-labeled (13C, 15N) sample of NCR044.1 (0.7
mM, 20 mM sodium acetate, 50 mM NaCl, pH 5.3) using Agilent (Inova-600 and -750) or
Bruker (Advent-750) spectrometers equipped with an HCN-probe and pulse field gradients. The
1H, 13C, and 15N chemical shifts of the backbone and side chain resonances were assigned from
the analysis of two-dimensional 1H-15N HSQC, 1H-13C HSQC, HBCBCGCDHD, and
HBCBCGCDCHE spectra and three-dimensional HNCACB, CBCA(CO)NH, HCC-TOCSY-
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23
NNH, CC-TOCSY-NNH, and HNCO spectra. The chemical shift assignments were assisted by
the analysis of three-dimensional 15N-edited NOESY-HSQC and 13C-edited NOESY-HSQC
(aliphathic and aromatic) spectra, collected with a mixing time of 90 ms, that also supplied the
NOE-based distance restraints required for the structure calculations. To improve the resolution
around the residual water resonance and obtain additional inter- and intra-residue proton side
chain restraints, a three-dimensional 13C-edited NOESY-HSQC (aliphathic) data set was
collected by lyophilizing and resuspending the sample in 99.8% D2O. In preparing the latter
sample, slowly exchanging amides were identified by collecting a short 1H-15N HSQC spectrum
after the addition of 99.8% D2O (~10 minutes later). To assess the effect of the disulfide bonds
on the structure of NCR044.1, the double-labeled (13C, 15N) sample in 99.8% D2O was
lyophilized, redissolved in 93% H2O/7% D2O, and made 5 mM with the strong reducing agent
tris(2-carboxyethyl)phosphine (TCEP). Similar two- and three-dimensional NMR experiments
used to assign the 1H, 13C, and 15N chemical shifts of oxidized NCR044.1 were used to assign
these resonances in the reduced state. An overall rotational correlation time, τc, was estimated
for NCR044.1 in the reduced and oxidized states from the ratio of collective backbone amide 15N
T1 and T1rho measurements47,47. A chemical shift perturbation study29 was performed with a 250
µL sample of oxidized NCR044.1 (0.07 mM) by titrating four times 2 µL aliquots of
phosphatidylinositol 3-phosphate diC8 (PI(3)P, 42.5 mM) (Echelon Biosciences, Salt Lake City,
UT) and collecting a 1H-15N HSQC after each addition. The molar ratio of PI(3)P:NCR044.1 at
each titration point was 4.7, 9.4, 14.1, and 18.8. All NMR data were processed using Felix2007
(MSI, San Diego, CA) software and analyzed with the program Sparky (v3.115). The 1H, 13C,
and 15N chemical shifts were referenced using indirect methods (DSS = 0 ppm) and deposited
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24
into the BioMagResBank database (www.bmrb.wisc.edu) under the accession number BMRB-
30660 (oxidized NCR044.1).
NMR solution structure calculations for oxidized NCR044.1
The 1H, 13C, and 15N chemical shift assignments and peak-picked NOESY data were used as
initial experimental inputs in iterative structure calculations with the program CYANA (v 2.1)48.
The assigned chemical shifts were also the primary basis for the introduction of 38 dihedral Psi
(ψ) and Phi (φ) angle restraints identified with the program TALOS+ using the online webserver
(https://spin.niddk.nih.gov/bax/nmrserver/talos/)49. Six restraints between the side chain sulfur
atoms of C9-C30 and C15-C25 (2.0-2.1 Å, 3.0-3.1 Å, and 3.0-3.1 Å for the Sγ-Sγ, Sγ-Cβ, and
Cβ-Sγ distances, respectively)21 were introduced on the basis of high resolution mass
spectrometry analysis. Four hydrogen bond restraints (1.8 – 2.0 Å and 2.7 – 3.0 Å for the NH–O
and N-O distances, respectively) were introduced on the basis of proximity in early structure
calculations and the observation of slowly exchanging amides in a deuterium exchange
experiment. The final ensemble of 20 CYANA derived structures were then refined with explicit
water with CNS (version 1.1) using the PARAM19 force field and force constants of 500, 500,
and 1000 kcal for the NOE, hydrogen bond, and dihedral restraints, respectively. For these water
refinement calculations the upper boundary of the CYANA distance restraints was left
unchanged and the lower boundary set to the van der Waals limit. Structural quality was assessed
using the online Protein Structure Validation Suite (PSVS, v1.3)50. Complete structural statistics
are summarized in Table 1. The atomic coordinates for the final ensemble of 19 structures have
been deposited in the Research Collaboratory for Structural Bioinformatics (RSCB) under PDB
code 6U6G.
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25
Antifungal activity assay
The antifungal activity of NCR044.1 against fungal pathogens was determined
spectrophotometrically using the 96-well plate assay as described previously51,52. The
quantitative fungal growth inhibition was determined by measuring the absorbance at 595 nm
using a (Tecan Infinite M200 ProTecan Systems Inc., San Jose, CA) microplate reader at 48 h.
IC50 and IC90 values were calculated with GraphPad software (version 8, San Diego, CA).
Fungal cell viability/cell killing was determined using the resazurin cell viability assay as
described previously52,53.
SYTOXTM Green (SG) membrane permeabilization assay
The effect of NCR044.1 on the membrane integrity of B. cinerea germlings was determined
using a modified SG uptake quantification assay45. Membrane permeabilization in B. cinerea
germlings exposed to different concentrations of NCR044.1 was measured every 30 min for 2 h.
SG uptake was quantified by measuring the fluorescence in a SpectraMax® M3
spectrophotometer (exc: 488; cutoff: 530; emi: 540 nm). Membrane permeabilization of B.
cinerea conidia (50 µl, 105 spores/ml) and germlings was measured after 15 min of exposure to
NCR044.1 (50 µL, 3 μM) using fluorescence confocal microscopy (Leica SP8-X) with an
excitation and emission wavelength of 488 and 508-544 nm, respectively.
Quantification of intracellular reactive oxygen species (ROS)
ROS production in B. cinerea germlings exposed to different concentrations NCR044.1 was
measured every 30 min for 2 h using the ROS indicator dye 2′,7′-dichlorodihydrofluorescein
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26
diacetate (H2DCF-DA, Invitrogen, Carlsbad, CA). ROS levels were quantified by measuring the
fluorescence in a SpectraMax® M3 spectrophotometer microplate reader (exc: 495; cutoff: 515;
emi: 529 nm). Intracellular ROS production in B. cinerea conidia and germlings exposed to 3
μM NCR044.1 was also imaged using fluorescence confocal microscopy (Leica SP8-X)39 with
an excitation and emission wavelength of 480 and 510-566 nm, respectively.
NCR044.1 uptake into fungal cells
NCR044.1 was labeled with DyLight550 amine reactive fluorescent dye following the
manufacturer’s instructions (Thermo Scientific, Waltham, MA). Confocal microscopy on a Leica
SP8-X was performed to monitor uptake of the fluorescently labeled NCR044.1 peptide as
described previously54 with minor modifications. Briefly, B. cinerea conidia (50 µl, 105
spores/ml) were treated with DyLight550-labeled NCR044.1 (50 µL, 1.5 and 3 µM), incubated at
room temperature overnight, and the fluorescence measured with excitation and emission
wavelengths of 550 and 569-611 nm, respectively. To monitor internalization of DyLight550-
NCR044.1 into B. cinerea germlings, 3D time-lapse confocal microscopy data were collected
every 3 min for 1 h. Co-localization experiments were performed to visualize the intracellular
distribution of DyLight550-NCR044.1 and the membrane-selective dye FM4-64 using an
excitation wavelength of 550 nm for both dyes with 560-600 and 680-800 nm emission
wavelengths, respectively. To determine if NCR044.1 targeted the nuclear DNA or nucleolus
region of B. cinerea, germlings were treated with 3 μM of DyLight500-NCR044.1 in the
presence of the DNA specific staining dye 4′,6-diamidino-2-phenylindole (DAPI, final
concentration: 0.1 µg/mL) or a RNA selective nucleolus specific staining dye (Nucleolus Bright
Green, final concentration: 1 μmol/L, Dojindo Molecular Technologies, Japan). Co-localization
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27
was visualized using a ZEISS Elyra 7 super-resolution microscope (Carl Zeiss Microscopy, Jena,
Germany) in lattice structured illumination microscopy mode at excitation and emission
wavelengths of 561 and 590 nm (DyLight550), 405 and 440 nm (DAPI), and 488 and 515 nm
(Nucleolus Bright Green), respectively. Single- or time-lapse z-stacks were acquired with a C-
Apochromat 63X water immersion objective lens (Numerical aperture = 1.2, 63 nm x-y and 371
nm z pixel size in leap mode) taking 15 phases per image with a 30 ms exposure.
Fluorescence Redistribution After Photobleaching (FRAP) experimental setup and analysis
The FRAP experiments were performed on a Leica SP8-X microscope (FRAP Wizard Module,
LAS X Version 3.1.5.16.16308) using the HC PlanApochromat 63X water immersion objective
lens (Numerical aperture = 1.2) with the pinhole set to 1 Airy unit and zoom set to 1.77. Images
were acquired for the selected cellular regions (germling cytoplasm, germling nucleoli, germling
cell wall, and spore cell wall) after 1 h incubation with peptide under the following identical
imaging and FRAP conditions: 10 pre-bleach and 700 post-bleach frames (512 x 64 pixels, pixel
size 204 nm) captured at 173 ms intervals without averaging using 550 nm excitation and 560-
625 nm emission wavelengths with a PMT detector and a transmitted light channel. The power
of the 550 nm laser was set at 3.5% during imaging to prevent the detection of bleaching for the
duration of each FRAP experiment (~3 min). A 1.52 µm2 circular bleach region was applied with
100% laser excitation power (550 nm wavelength) for 3.5 s immediately following pre-bleach
and prior to post-bleach imaging. FRAP analysis was performed on 24 datasets for each
subcellular region showing no evidence of sample drift during acquisition. A single exponential
curve fitting function was applied post-acquisition to extract the half-maximum tau (τ½), mobile
fraction, and immobile fraction for each condition.
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28
Peptide distribution on the plant surface
The distribution of DyLight550-NCR044.1 on tobacco leaf surfaces was characterized by
incubating leaves with 24 uM of labeled peptide for 1 h, air drying, and imaging on a Leica SP8-
X confocal microscope equipped with an HC PlanApochromat 63X water immersion objective
lens (Numerical aperture = 1.2) with the pinhole set to 1 Airy unit. Simultaneous excitation with
405 and 560 nm laser wavelengths was used to visualize cell wall auto- (426 – 485 nm) and
DyLight550- (560 – 600 nm) fluorescence using photo-multiplier tube (PMT) detection of a
transmitted light channel. Three-dimensional volumes were created using a 1 µm z-interval for
each treatment and rendered with a 3D maximum intensity projection.
NCR peptide-phospholipid interactions
NCR044.1-phospholipid interactions were determined using PIP StripsTM (Echelon Biosciences,
Salt Lake City, USA) as described previously54 with minor modifications. The binding of
NCR044.1 to the phospholipids on the strips was detected using a polyclonal antibody generated
in rabbits with custom-synthesized NCR044.1 (Biomatik Corp., Cambridge, ON, CDN). Binding
of NCR044.1 to PI4P and PI(3,5)P2 was determined using the PolyPIPosomes (Echelon
Biosciences, Salt Lake City, USA) assay as described38. Samples were reduced with 100mM
dithiothreitol (DTT), separated on a 4-20% (Bio-Rad, TGX™ precast gels) SDS-PAGE gel, and
then stained with Instant Blue (Expedeon, Cambridge, UK).
Semi-in planta antifungal activity of NCR044.1 against B. cinerea
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29
Detached rose petal and lettuce leaf infection assays were performed as described previously55
with minor modifications. Briefly, store-bought rose petals or ~2 x 2 cm cut pieces of iceberg
lettuce were placed in petri dishes. A 10 μl aliquot of NCR044.1 was spotted onto the plant
samples at different peptide concentrations and inoculated with 10 μL of B. cinerea spores (105
spores/mL suspended in 2X SFM buffer). The petri dishes were inserted into Ziploc
WeatherShield plastic boxes containing a wet paper towel to maintain a high humidity.
Following incubation at room temperature for 48 h the leaves were photographed and the lesion
size was determined using ImageJ software.
Evaluation of NCR044.1 as sprayable peptide for protection against gray mold disease
The tomato (Solanum lycopersicum cv. Mountain Spring) and tobacco (Nicotiana benthamiana)
plants were grown in a controlled environment growth chamber for two and four weeks,
respectively, under a 16/8 h and 12/12 h light/dark cycle, respectively. Whole plants were then
sprayed with water or NCR044.1 (24 µM), allowed to dry for 1 h, sprayed with a 5 × 104 B.
cinerea fungal spore suspension prepared in half-strength SFM medium, and placed in a highly
humid environment. After 48 h, high-resolution fluorescence images were taken using
CropReporter (PhenoVation, Wageningen, Netherlands). The quantification of plant health/stress
was carried out using the calculated FV/FM (maximum quantum yield of photosystem II) images
of the CropReporter, showing the efficiency of photosynthesis in false colors.
Statistical Analysis
Statistical analysis was performed in the R environment (version 3.5.2) using RStudio (version
1.1.463). The normality and homogeneity of variance was evaluated using a Shapiro-Wilk test
and F-test/Levene’s test, respectively. A parametric unpaired Student’s t test was used to
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compare the significant difference between two groups of normally distributed data. The non-
parametric Kruskal-Wallis test was performed on non-normally distributed data to compare
significant differences of more than two groups. A pairwise Wilcoxson test with an Holm-
Bonferroni p-value correction was applied to find significant differences between groups.
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Acknowledgments
The generous support from TechAccel for part of the research reported here is acknowledged.
The structure for NCR044.1 was solved using resources at the W.R. Wiley Environmental
Molecular Sciences Laboratory, a national scientific user facility sponsored by U.S. Department
of Energy’s Office of Biological and Environmental Research (BER) program located at Pacific
Northwest National Laboratory (PNNL). Battelle operates PNNL for the U.S. Department of
Energy. We also acknowledge imaging support from the Advanced Bioimaging Laboratory at
the Danforth Plant Science Center and usage of the Leica SPX-8 acquired through an NSF Major
Research Instrumentation grant (DBI-1337680).
Author Contributions.
S.V., K.C., and D.S. conceived the research. S.V., K.C., H.L., G.B., and D.S. designed the
research. S.V., H.L., J.S., and G.B. conducted the experiments. S.V., K.C., H.L., J.S., G.B., and
D.S. analyzed and interpreted the results. S.V., K.C., G.B., and D.S. wrote the manuscript with
help from H.L.
Competing interests. The authors declare no competing interests.
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38
Figure Legends
Figure 1. Amino acid sequences and properties of NCR044.1 and NCR044.2 and expression of their genes in root nodules of Medicago truncatula cv. Jemalong A17. a. Primary amino acid sequences of the signal and mature peptide sequences of NCR044.1 and NCR044.2. Mature peptide sequences are each 36 residues in length. Conserved cysteine residues are highlighted in red and six non-conserved residues are highlighted in blue. b. Net charge, hydrophobic amino acid content, and molecular weight of the mature NCR044.1 and NCR044.2 peptides. c. Gene expression analysis of NCR044.1 and NCR044.2 in root nodules and roots at 10 days post-infection (dpi) by Sinorhizobium meliloti. d. NCR044.1 and NCR044.2 transcript abundance in laser-dissected zones of mature nodules at 15 dpi. FI: nodule meristematic zone - Fraction I; FIId: infection zone – distal fraction; FIIp: early differentiation zone - proximal fraction; IZ: late differentiation zone - interzone II–III; ZIII: nitrogen-fixation zone. Web-based RNA-seq data are available at the Symbimics website (https://iant.toulouse.inra.fr/symbimics).
Figure 2. Solution structure of NCR044.1. a-b. Assigned 1H-15N HSQC spectra for NCR044.1 (0.7 mM) collected in the oxidized (disulfide) (a) and reduced (dithiol) (b) states. Spectra collected at 20 °C in 20 mM sodium acetate, 50 mM NaCl, pH 5.3 at a 1H resonance frequency of 600 MHz. Amide side chain resonance pairs are connected by a red dashed line, guanidium protons of the six arginine residues are in the cyan circle (not visible in the reduced state), and folded resonances are identified with an asterisk. The three cross peaks circled in magenta in reduced NCR044.1 are resonances for R26, R32, or R33 that could not be unambiguously assigned. c. Cartoon representation of the backbone superposition of the ordered regions in the ensemble of 19 structures calculated for oxidized NCR044.1 (6U6G). Beta-strands are colored blue and the α-helix is colored red. d. Cartoon representation of the NCR044.1 structure closest to the average with a stick representation of the four cysteine side chains highlighted in yellow. e. Analysis of the side chain 13C chemical shifts in the reduced (dithiol) and oxidized (disulfide) states. The observed 13Cα and 13Cβ chemical shift deviations from random coil values for oxidized and reduced NCR044.1 where Δδ13C = δObserved – δRandon coil. The random coil carbon values were taken from CNS (cns_solve_1.1) with no calculations for the oxidized cysteine residues. Blue and red = oxidized, cyan and orange = reduced. On top of the graph is a schematic illustration of the elements of secondary structure observed in the NMR-derived structure with the α-helix colored red and β-strands colored blue.
Figure 3. Antifungal activity of NCR044.1 against B. cinerea and Fusarium spp. a. IC50 and IC90 values of NCR044.1 for each pathogen are shown. Data are means ± SEM of three independent biological replications (n = 3). b. Results of the fungal cell viability assay using resazurin, a metabolic indicator of living cells. A change from blue to pink/colorless signals resazurin reduction and indicates metabolically active fungal cells. In the presence of 3 or 6 µM NCR044.1, fungal cells lost their metabolic capacity and did not reduce resazurin c. Representative microscopic images showing the inhibition of B. cinerea growth 24 - 48 h after
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treatment with 1.5 or 3 µM of NCR044.1 (right). B. cinerea without peptide added served as a negative control (left). (Scale bar: 20 µm).
Figure 4. Membrane permeabilization activity of NCR044.1. a-d. Confocal microscopy images, e-h. Corresponding bright field images (e-h) of SYTOXTM Green (SG) uptake in B. cinerea conidia and germlings treated with 3 µM NCR044.1 for 15 min. (Scale bar: 10 µm). SG (green) labeled nuclei in conidia and germlings treated with NCR044.1 indicate increased plasma membrane permeability. i. Real time-quantification of cell membrane permeability in B. cinerea germlings treated with various concentrations of NCR044.1. Membrane permeabilization increased with increasing concentrations of peptide. Data are means (large dots) ± SEM of three biological replications (n = 3, small dots). j. Representative microscopic images of B. cinerea spore germination without peptide (left). k. B. cinerea growth inhibition in the presence of 3 µM NCR044.1 (middle). l. The germination of B. cinerea spores 24 h after removal of 3 µM NCR044.1 after treatment for 1 h (right). (Scale bar: 10 µm). Fungal growth after removal of the peptide indicates that membrane permeabilization is insufficient for fungal cell killing.
Figure 5. Phospholipid binding of NCR044.1. a. PIP strip showing strong binding of NCR044.1 to phosphatidylinositol diphosphate PI(3,5)P2 and weak binding to multiple phospholipids, including phosphatidylinositol monophosphates PI(3)P, PI(4)P and PI(5)P, phosphatidylinositol di/tri-phosphates PI(3,4)P2, PI(4,5)P2, PI(3,4,5)P3, and phosphatidic acid (PA). b. Densitometry analysis of PIP strip probed with NCR044.1. Data are means ± SEM of three independent biological replications (n = 3, small dots). c. PolyPIPosome binding assay showing strong binding of NCR044.1 to PI(4)P and PI(3,5)P2 and weak binding to PC:PE.
Figure 6. Translocation of exogenous NCR044.1 into B. cinerea cells. a-b. Confocal microscopy images of B. cinerea conidia showing the uptake of DyLight550-NCR044.1. NCR044.1 first accumulated on the cell surface and was internalized inside the B. cinerea conidia after overnight incubation (Scale bar: 2 µm). c. Percentage of B. cinerea conidia that internalized DyLight550-NCR044.1 following overnight incubation with 1.5 and 3 µM labeled peptide. Data are means ± SEM of three independent biological replications (n = 3, small dots). Asterisks denote significant differences (**P<0.01, unpaired Student’s t test). d-i. Confocal microscopy images of B. cinerea spores and germlings showed the internalization and co-localization of 3 µM Dylight550-NCR044.1 (red) with membrane-selective dye FM4-64 (green). DyLight550-NCR044.1 bound to the cell wall (arrows) and cell membranes (arrow heads). DyLight550-NCR044.1 co-localized with FM4-64 and bright focal accumulations at the germ tube tip (asterisks) and intermittently adjacent to cell walls (F) of B. cinerea. DyLight550-NCR044.1 localization to nuclear region (N) (Scale bar: 2 µm). j. Time-lapse confocal microscopy images of B. cinerea germlings showed internalization of Dylight550-NCR044.1 (white) over ~ 40 min. Peptide first accumulated along cell wall (T = 0), and then entered inside the B. cinerea at foci (asterisks) at the germ tube tip or along the germ tube and/or conidial walls (T = 0 through T = 9:51 minutes). Peptide was diffusely localized into the cytoplasm and a strong signal was observed throughout the nuclear region of spore heads and germlings (T = 9:51 through 36:41 minutes). Bright field images at T = 0 and T = 36:41 show loss of turgor and cytoplasmic vacuolization (Scale bar: 10 µm).
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Figure 7. Subcellular localization of fluorescently labeled DyLight550-NCR044.1 in B. cinerea germlings. a. Super-resolution structured illumination microscopy (SR-SIM) images of B. cinerea germlings showed the internalization of DyLight550-NCR044.1 (red). DyLight550-NCR044.1 was targeted at elevated levels to the nucleus in B. cinerea germlings (asterisks). b-d. DyLight550-NCR044.1 (b) did not co-localize with the DNA-specific DAPI (asterisks) stain (c), but, co-localized with rRNA specific Nucleolus Bright Green stain (d) suggesting that NCR044.1 specifically targeted the nucleolus. Images were taken after 1 h of exposure to 3 µM DyLight550-NCR044.1 (Scale bar: 2 µm).
Figure 8. Fluorescence Recovery After Photobleaching. a. Representative normalized fluorescence recovery curves of DyLight550-NCR044.1 showed relative differences in mobility of key subcellular compartments in B. cinerea. DyLight550-NCR044.1 recovery in the germling cytoplasm (light blue) had the greatest overall mobility compared with germling nucleoli (red), germling cell walls (brown) and spore cell walls (blue). Spore cell walls exhibited the least mobility (dark blue) of all measured compartments. Recovery data derived from a was normalized to 1 and the x and y- axis was set to the origin “0”. b. The immobile fraction (%) data are represented using a boxplot and tabulation of the average values (c). The immobile fraction (representing tightly bound peptide) was relatively low for the cytoplasm (11.7 ± 1.5 %), nucleoli (15.4 ± 1.9 %), and germling cell walls (24.9 ± 3.2 %) but significantly greater for spore cell walls (76.7 ± 1.3 %). d. Half-time of recovery (τ½) data are represented using a boxplot and tabulation of the average values (e). NCR044.1 mobile fractions showed relatively quick recovery (τ ½ = 22.0 ± 1.7 s) in the germling cytoplasm and germling cell walls cell wall (τ ½ = 20.5 ± 3.4 sec) while nucleoli (τ ½ = 31.4 ± 2.4 s) and spore cell walls (τ ½ = 36.0 ± 2.4 s) exhibited reduced mobility suggesting stronger interactions with these structures. Each colored boxplot represents the 25th and 75th percentiles (box) and the whisker represents 1.5 times the interquartile range (IQR) from the 25th and 75th percentiles. The horizontal line in the box plot represents the median with the mean ± SEM denoted by a dot. Outliers are indicated by large dots outside 1.5*IQR above the first and third quartile. The individual measurements of mobile and immobile fractions are indicated on the left of each boxplot and represent the variances of the samples. The number (n = 24) of different subcellular compartments in B. cinerea analyzed are indicated below each group in the boxplot and are from at least three independent experiments. Asterisks represent significant differences between different subcellular compartments (*P<0.05, **P<0.01 ***P<0.001, ****≤0.0001, pairwise Wilcoxson test with Holm correction, Kruskal–Wallis for multiple groups).
Figure 9. Spray application of NCR044.1 confers gray mold resistance in N. benthamiana and tomato plants. Four-week-old Nicotiana benthamiana (a) and two-week-old Solanum lycopersicum L. cv. Mountain Spring plants (c) sprayed with either 2 mL water or NCR044.1 (24 μM) prior to exposure with a spray containing 1 mL of a 5 × 104 B. cinerea fungal spore suspension. Maximum quantum yield of PSII photochemistry (Fv/Fm) and the chlorophyll (Chl) index were measured at 48 h and 60 h, respectively, after fungal exposure. The false color gradient scale next to the figure indicates the efficiency of photosynthesis. Red (Fv/Fm) or black (Chl) colors represent a low efficiency of photosynthesis, characteristic of stress caused by the interaction between the fungus and plant. Green (Fv/Fm) or grey (Chl) colors indicate a higher
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efficiency of photosynthesis. NCR044.1 significantly protected tobacco and tomato plants from gray mold disease caused by B. cinerea. The calculated photosynthetic quantum yield (Fv/Fm) of tobacco (b) and tomato (d) plants. Each colored boxplot represents the 25th and 75th percentiles (box) and the whisker represents 1.5 times the interquartile range (IQR) from the 25th and 75th percentiles. The horizontal line in the box plot represents the median with the mean ± SEM denoted by a dot. Outliers are indicated by large dots outside 1.5*IQR above the first and third quartile. The individual measurements of Fv/Fm are indicated on the left of each boxplot and represent the variances of the samples. The number (n = 12) of plants tested is indicated below each group in the boxplot and is from at least two independent experiments for tobacco. Similar results were observed in a third independent experiment, except the data was collected 60 h after fungal exposure. The number (n = 15) of plants tested is indicated below each group in the boxplot and is from at least three independent experiments for tomato. Asterisks represent significant differences between different groups (*P<0.05, **P<0.01 ***P<0.001, ****≤0.0001, pairwise Wilcoxson test with Holm correction, Kruskal–Wallis for multiple groups). Figure 10. Proposed multi-step model for the antifungal action of NCR044.1 against B. cinerea. a. NCR044.1 binds to cell wall b. NCR044.1 binds to plasma membrane, induces membrane permeabilization and loss of turgor pressure, is internalized and induces ROS production c. NCR044.1 diffuses through the cytoplasm to nucleoli and likely interacts with ribosomes leading to inhibition of translation and ultimately fungal cell death.
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Figure 1
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Figure 2
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Figure 3
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Figure 4
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Figure 5
(which was not certified by peer review) is the author/funder. All rights reserved. No reuse allowed without permission. The copyright holder for this preprintthis version posted February 20, 2020. . https://doi.org/10.1101/2020.02.19.956318doi: bioRxiv preprint
47
Figure 6
(which was not certified by peer review) is the author/funder. All rights reserved. No reuse allowed without permission. The copyright holder for this preprintthis version posted February 20, 2020. . https://doi.org/10.1101/2020.02.19.956318doi: bioRxiv preprint
48
Figure 7
(which was not certified by peer review) is the author/funder. All rights reserved. No reuse allowed without permission. The copyright holder for this preprintthis version posted February 20, 2020. . https://doi.org/10.1101/2020.02.19.956318doi: bioRxiv preprint
49
Figure 8
(which was not certified by peer review) is the author/funder. All rights reserved. No reuse allowed without permission. The copyright holder for this preprintthis version posted February 20, 2020. . https://doi.org/10.1101/2020.02.19.956318doi: bioRxiv preprint
50
Figure 9
(which was not certified by peer review) is the author/funder. All rights reserved. No reuse allowed without permission. The copyright holder for this preprintthis version posted February 20, 2020. . https://doi.org/10.1101/2020.02.19.956318doi: bioRxiv preprint
51
Figure 10
(which was not certified by peer review) is the author/funder. All rights reserved. No reuse allowed without permission. The copyright holder for this preprintthis version posted February 20, 2020. . https://doi.org/10.1101/2020.02.19.956318doi: bioRxiv preprint